JP6852756B2 - Heads-up display (HUD) mirror assembly and housing - Google Patents

Description

The present disclosure relates to a vehicle head-up display (HUD) mirror assembly, and more specifically to a HUD mirror assembly that includes a concave mirror.

The head-up display (HUD) device can be used in the vehicle to display a virtual image that is visually recognizable by the occupants of the vehicle. The virtual image can be projected from a concave mirror that is part of the HUD device. The concave mirror can be part of an assembly that is installed behind the instrument panel of an automobile. Alignment of the concave mirror within the concave mirror assembly is important to maintain proper operation of the HUD device.

In one embodiment, a head-up display (HUD) mirror assembly is disclosed. The HUD mirror assembly includes mirrors that have front and rear surfaces and extend along the longitudinal axis. The HUD mirror assembly also includes a housing having a peripheral frame portion and a rear body portion connected to each other to accommodate the mirror so that the front surface of the mirror is exposed. The first and second pegs extend away from the peripheral frame and along the longitudinal axis. The HUD mirror assembly further includes brackets with first and second attachments, each containing first and second slots, and a support arm extending between them. The HUD mirror assembly also includes tension springs and torsion springs. The tension spring is attached to the rear body and the support arm. The torsion spring exerts a holding force on the housing along the longitudinal axis from the second peg toward the housing. The first peg is supported on the first slot by the support surface of the first peg when the mirror assembly is in the first and second assembled forms.

In another embodiment, a head-up display (HUD) mirror housing is disclosed. The HUD mirror housing includes a peripheral frame portion extending along the longitudinal axis, a rear main body portion connected to a peripheral frame portion connected to each other to accommodate the mirror so that the reflecting surface of the mirror is exposed, and a peripheral frame. Includes first and second pegs that extend away from the portion and along the longitudinal axis. In this embodiment, the first peg has a first support surface configured to be supported by a first bracket mounting slot when the HUD mirror housing is in the assembled form.

In yet another embodiment, a method of assembling a head-up display (HUD) mirror assembly is disclosed. The HUD mirror assembly is separated from a mirror having front and rear surfaces extending along a longitudinal axis, a peripheral frame portion and a rear body portion connected to each other to accommodate the mirror so that the front surface of the mirror is exposed, and a peripheral frame portion. A housing with first and second pegs that extend in the direction and along the longitudinal axis, and first and second attachments that include first and second slots, respectively, and a support arm that extends between them. The first slot has a major axis and a minor axis, including a bracket with and. The method is to move the housing vertically downward along the long axis so that the first peg sits on the underside of the first slot, and so that the support surface of the first peg sits on the back surface of the first slot. Includes moving the housing laterally away from the bracket, along the longitudinal axis.

FIG. 1 shows a schematic view of a head-up display device according to an embodiment. FIG. 2 shows a rear view of the mirror assembly according to one embodiment. FIG. 3 shows a fragmentary top view of the first side pegs and slots of the mirror assembly in the intended assembly form according to one embodiment. FIG. 4 shows a partial cross-sectional view of the first side pegs and slots of the mirror assembly in the intended assembly form shown in FIG. FIG. 5 shows a fragmentary top view of the first side pegs and slots of the mirror assembly in an unintended assembly form according to one embodiment. FIG. 6 shows a partial cross-sectional view of the first side pegs and slots of the mirror assembly in the unintended assembly form shown in FIG. FIG. 7 shows a perspective side view of the first side pegs and slots in the intended assembly form shown in FIG. FIG. 8 shows a fragmentary top view of the first side pegs and slots of the mirror assembly in the first assembly embodiment according to one embodiment. FIG. 9 shows a partial cross-sectional view of the first side pegs and slots of the mirror assembly in the first assembly configuration as shown in FIG. FIG. 10 shows a fragmentary top view of the first side pegs and slots of the mirror assembly in the second assembly embodiment according to one embodiment. FIG. 11 shows a partial cross-sectional view of the first side pegs and slots of the mirror assembly in the second assembly mode as shown in FIG. FIG. 12 shows a perspective side view of the first side peg and the slot in the first assembled form shown in FIG. FIG. 13a shows a perspective side view of the mirror assembly during the first assembly step according to one embodiment. FIG. 13b shows a perspective side view of the mirror assembly of FIG. 13a during the second assembly step. FIG. 13c shows a perspective side view of the mirror assembly of FIG. 13a in the intended final assembly form.

As appropriate, detailed embodiments of the invention are disclosed herein. However, it should be understood that the disclosed embodiments are merely exemplary of the invention, which can be embodied in various and alternative forms. The figure is not always the exact scale. Some features may be exaggerated or minimized to show details of a particular component. Therefore, the particular structural and functional details disclosed herein should not be construed as limiting, but merely a representative for teaching those skilled in the art to use the invention in various ways. Should be interpreted as a basic basis.

FIG. 1 shows a schematic view of a head-up display (HUD) device 10 according to an embodiment. The HUD device 10 is arranged in the instrument panel 12 of the vehicle 14. The HUD device 10 projects an image on the windshield 16 of the vehicle 14. The windshield 16 is configured to project an image as a virtual image 18 visible to the vehicle occupant 20. The virtual image 18 may include various information recognizable by the vehicle occupant 20. Non-limiting examples of such information include vehicle condition information such as vehicle speed, fuel consumption, fuel consumption, mileage, and average number of miles per gallon, as well as, for example, outside air temperature, room temperature. Includes vehicle environment information such as weather information, road condition information, and navigation information.

The HUD device 10 is a controller configured to execute instructions, commands, and other routines stored in memory 23 to support the functionality of the HUD device 10, as disclosed herein. 22 is included. Instructions, commands, and other routines executed by controller 22 may be stored non-volatilely in memory 23 using any suitable processor-readable medium or storage device, including any non-transient medium. Good. In one or more embodiments, the controller 22 is configured to execute a command to change the angle or orientation of the mirror 24 of the HUD device 10 with respect to the windshield 16. In one or more embodiments, the controller 22 is configured to execute an instruction to transmit a signal to the display device 26. The display device 26 can be a laser scanner. Other non-limiting examples of display devices include display devices that use thin film transistor (TFT) or digital light processing (DLP) technology. As shown in FIG. 1, a laser scanner as an example of a display device 26 is configured to convert a signal into an image projected onto a screen 28. The screen 28 is configured to project an image received from the display device 26 onto the mirror 24. The mirror 24 is configured to project the image received from the screen 28 onto the windshield 16 via the medium 32, which in turn produces a virtual image 18. The medium 32 may be an opening formed in the instrument panel 12 or a transparent window installed in the opening of the instrument panel 12.

During assembly of the HUD device 10, the mirror 24 is mounted within the housing 30. The integrated unit of the mirror 24 and the housing 30 is attached to the bracket 33. The mirror 24, the housing 30, and the bracket 33 may be collectively referred to as a mirror assembly 34. The mirror assembly 34 may further include a drive unit 36 configured to change the angle or orientation of the mirror 24 with respect to the windshield 16 based on the signal received from the controller 22.

FIG. 2 shows a rear view of the mirror assembly 100 according to one embodiment. The mirror assembly 100 includes a mirror 102, a housing 104, a drive unit 106, and a bracket 108. In one or more embodiments, the mirror 102 is a concave mirror. The mirror 102 includes a front surface and a rear surface on the opposite side. Although not shown in FIG. 2, they are obscured by the housing 104 so that the front faces the page, the back faces the outside of the page, and faces the housing 104. The front surface includes a reflective material for reflecting the image projected from the screen 28 onto the mirror 102 onto the windshield 16.

The housing 104 is configured to accommodate the mirror 102. The housing 104 can be made of a molded polymer material having the strength required to accommodate and support the mirror 102. The housing 104 includes a peripheral frame portion 110, a rear main body portion 112, a first side peg 114, a second side peg 116, and a mounting portion 118. The peripheral frame portion 110 of the housing 104 covers the peripheral edge portion 120 of the mirror 102 at least partially. The rear body 112 of the housing 104 covers, at least partially, the rear surface of the mirror 102. Several clasps, such as clasps 122, are formed on the peripheral frame portion 110 of the housing 104. Several fasteners, such as fasteners 124, are formed on the rear body 112 of the housing 104. In other embodiments, some clasps may be formed on the rear body portion 112 and some fasteners may be formed on the peripheral frame portion 110. Corresponding clasps and clasps mesh with each other to attach the peripheral frame portion 110 and the rear body portion and hold the mirror 102 therein. The first side peg 114 protrudes outwardly and integrally from the first side wall 126 of the rear main body portion 112. The second side peg 116 projects outwardly and integrally from the second side wall 128 of the rear main body 112. The mounting portion 118 extends from the second side wall 128 of the rear main body portion.

The bracket 108 includes a first mounting portion 130, a second mounting portion 132, a third mounting portion 134, a first support arm 136 extending between the first mounting portion 130 and the second mounting portion 132, and a second mounting portion 132. Includes a second support arm 138 extending between the and third mounting portion 134. The bracket 108 can be made of a punched metal alloy having the strength required to support the housing 104. The first mounting portion 130 includes a first vertical portion 140 and a first horizontal portion 142. The first horizontal portion 142 includes several openings (not shown) for mounting the bracket 108 to the mounting surface within the instrument panel 12. In one or more embodiments, the first horizontal portion 142 is mounted so that it is at least substantially parallel to the forward plane of the vehicle 14, whereas in other embodiments the mounting angle is relative to the forward plane of the vehicle 14. Not substantially parallel. The second mounting portion 132 includes a second vertical portion 144 and a second horizontal portion 146. The second horizontal portion 146 includes several openings (not shown) for mounting the bracket 108 to the mounting surface within the instrument panel 12. In one or more embodiments, the second horizontal portion 146 is mounted so that it is at least substantially parallel to the forward plane of the vehicle 14, whereas in other embodiments the mounting angle is with the forward plane of the vehicle 14. Not substantially parallel. The second vertical portion 144 is configured to mount the drive unit 106 on the mounting bracket 108. The third mounting portion 134 includes a third vertical portion 148.

The drive unit 106 includes a motor for driving a pinion that meshes with the teeth of the rack 150. The rotational movement of the pinion moves the rack 150 in an arcuate path with respect to the pinion. The rack 150 is connected to the peg 152 of the drive unit 106. The peg 152 communicates with the second side peg 116 of the housing 104. Since the peg 152 and the rack 150 are connected, the peg 152 communicates with the second side peg 116 of the housing 104, and the housing 104 and the mirror 102 are connected, the movement of the rack 150 along the arcuate path is the second side peg 116. Causes a rotational movement of the mirror 102, which causes the mirror 102 to change the orientation angle of the bracket 108 with respect to the first horizontal portion 142 and the second horizontal portion 146. The motor is configured to receive a signal transmitted by the controller 22 to instruct the motor to drive the pinion in either the first or second rotation direction. The pinion and rack 150 mesh with each other so that the rotational movement of the pinion is properly transferred to the rack 150. If the pinion and rack 150 are not properly meshed during the operation of the mirror assembly 100, this rotational movement may not be properly transferred.

The first vertical portion 140 of the first mounting portion 130 includes a first slot configured to accommodate the first side peg 114 of the mirror assembly 100. As further described herein and shown in the drawings, the first side peg 114 is received in the first slot in the assembled state. The second vertical portion 144 of the second mounting portion 132 includes a second slot configured to receive the second side peg 116. The third vertical portion 148 of the third mounting portion 134 includes a third slot for receiving the peg 152 of the drive unit 106. The surface of the rack 150 facing the peg 152 abuts on the mounting portion 118 of the housing 104. The mounting portion 118 also includes an opening for receiving a portion extending from the rack surface so as to communicate with the second side peg. In this assembled form, the drive unit 106 and the housing 104 (including the mirror 102) rotate the first and second side pegs 114, 116 and the drive unit peg 152 when these pegs are driven by the drive unit 106. Through exercise, it moves together with respect to the bracket 108.

In one or more embodiments, the tension spring 154 and the torsion spring 156 are configured to keep the mirror assembly 100 in a functional state when in the assembled form. The tension spring 154 includes first and second hook ends and a coil extending between them. The rear body 112 includes a notch 158 configured to accept the first hook end of the tension spring 154 when the mirror assembly 100 is in assembled form. The first support arm 136 of the bracket 108 includes a tab 160 including an opening configured to receive a second hook end of the tension spring 154 when the mirror assembly 100 is in the assembled form. In the assembled form, the tension spring 154 exerts a force along the longitudinal axis of the tension spring 154, as indicated by arrow 162 and as described in more detail below. This force is configured to prevent unintended movement of the mirror 102 in a direction that is at least partially opposed to this force.

The torsion spring 156 includes first and second linear ends and a coil extending between them. In the assembled form, the peg 152 of the drive unit 106 is seated in the coil of the torsion spring 156. The first linear end of the torsion spring is housed in an opening formed in the third vertical portion 148 of the third mounting portion 134 of the bracket 108. In the assembled form, the torsion spring 156 is located between the mounting portion 118 of the housing 104 and the third vertical portion 148 of the third mounting portion 134 of the bracket 108. As described in more detail below, the torsion spring 156 limits the effects of torsional and linear forces on the mirror assembly 100, i.e., with respect to the external force acting on the housing 104, the moment along the longitudinal axis and By exerting a holding force along the longitudinal direction on the housing 104, the housing 104, including the first side peg 114, is configured to be held in a suitable lateral position with respect to the bracket 108.

3 to 7 show the mirror assembly 200 according to one embodiment. These figures show the interaction between the first side peg 202 and slot 204 when the mirror assembly 200 is in assembled form. FIG. 3 shows a fragmentary top view of the first side peg 202 and slot 204 in the intended, assembled form. FIG. 4 shows a partial cross-sectional view of the first side peg 202 and slot 204 in the intended, assembled form. FIG. 5 shows a fragmentary top view of the first side peg 202 and slot 204 in an unintended, assembled form. FIG. 6 shows a partial cross-sectional view of the first side peg 202 and slot 204 in an unintended, assembled form. FIG. 7 shows a perspective side view of the first side peg 202 and slot 204 in the intended, assembled form.

As shown in FIGS. 3, 4, and 7, the first side peg 202 sits in slot 204 in the intended assembly form. Slot 204 includes opposing first and second upper chamfers 206 and 208 that connect to first and second upper portions 210 and 212, respectively. The ends of the arcuate lower part 214 of slot 204 are terminated by upper portions 210 and 212. The chamfered portions 206 and 208, as well as the side portions 210 and 212, are configured to guide the first side peg 202 along a downward vertical path towards the arcuate lower part 214 during the process of assembling the mirror assembly 200. The arcuate lower part 214 includes first and second circular segments 216 and 218 connected by a rectangular segment 220.

The first side peg 202 includes an end cap 222, a base 224, and a sliding portion 226 extending between the end cap 222 and the base 224. The end cap 222 can be circular. The base 224 can also be circular. As shown in the figure, the sliding portion 226 includes a part of the end cap 222, a base portion 224, and first and second slots 228 and 230 defined by the sliding portion 226, respectively. The lower surfaces of the slots 228 and 230 may be flat. In other embodiments, the lower surface of each slot 228, 230 may be arcuate.

As shown in FIGS. 3, 4, and 7, in the intended assembly mode, the support surface 232 of the first side peg 202 is mounted in slot 204. In an unintended assembly, high lateral impact forces (eg, 8G and above, but this threshold may vary by design) causes the mirror assembly 200 to laterally as shown by arrow 164 in FIG. It moves and causes the support surface 232 to fall off. In this state, as shown by arrow 162 in FIG. 2, the force of the tension spring 154 may prevent the mirror assembly 200 from returning to its intended assembly position. Arrow 234 in FIG. 7 indicates a component of the tensile spring force acting in the x direction (that is, the direction perpendicular to the long axis of the slot 204) with respect to the outer surface of the first support arm 236. Although not shown in this figure, there is also a force component in the y direction (ie, the direction parallel to the long axis of slot 204). In an unintended assembly, the pinion of the drive unit 106 and the rack 150 may not mesh properly, causing a malfunction in the operation of the mirror 102. Unintended assembly forms are shown in FIGS. 5 and 6. Instead of the first side peg 202 being seated in slot 204 on the support surface 232, the first side peg 202 is seated in slot 204 at first slot 228.

Another embodiment has a slot 300 having a contour different from that of the slot 204 and a first side peg 302 having a structure different from that of the first side peg 202. Due to these differences, the above-mentioned unintended assembly form can be avoided. 8 to 12 show the mirror assembly 304 according to another embodiment. These figures show the interaction between the first side peg 302 and the slot 300 when the mirror assembly 304 is in the assembled form. FIG. 8 shows a fragmentary top view of the first side peg 302 and the slot 300 in the first assembled form. FIG. 9 shows a partial cross-sectional view of the first side peg 302 and the slot 300 in the first assembled form. FIG. 10 shows a fragmentary top view of the first side peg 302 and the slot 300 in the second assembled form caused by the impact force in the left-right direction. FIG. 11 shows a partial cross-sectional view of the first side peg 302 and the slot 300 in the second assembled form. FIG. 12 shows a perspective side view of the first side peg 302 and the slot 300 in the first assembled form.

As shown in FIGS. 8-12, the first side peg 302 includes a peg slot 306, facing support surfaces 308, a base 310, and an end cap 312. The end cap 312 can be circular. The base 310 may also be circular. As shown in the figure, the peg slot 306 is bounded by an end cap 312 and a base 310. The lower surface of the peg slot 306 may be flat. In other embodiments, the lower surface of the peg slot 306 may be arcuate. As shown in FIGS. 8-12, the slot 300 includes a front upper chamfered portion 314 and a rear upper chamfered portion 316 connected to the front side portion 318 and the rear side portion 320, respectively. Slot 300 also includes a front arced portion 322 that is connected to the rear side portion 320 via a bottom portion 324 and a lower chamfered portion 326.

As shown in the first assembled form of FIGS. 8, 9, and 12, the first side peg 302 rests on the support surface 308 on the rear side 320 of the slot 300. As shown, the support surface 308 is circular, but can have other arched shapes. As indicated by arrow 164 in FIG. 2, a high lateral impact force (eg, 8G or higher, but this threshold may vary by design) causes the mirror assembly 304 to shift laterally. In this state, i.e., in the second assembly mode as shown in FIGS. 10 and 11, the first side peg 302 continues to sit on the rear side 320 of the slot 300 on the support surface 308. After the large lateral impact is finished, the mirror assembly 304 is free to return to the first assembled form. However, in any assembly mode, the support surface 308 and the slot so that the force of the tension spring 154 does not prevent the mirror assembly 304 from returning to the intended assembly position, as indicated by arrow 162 in FIG. Contact with the 300 is maintained. Therefore, unintended assembly positions are not experienced in one or more embodiments due to lateral forces and tensile spring forces.

13a through 13c show side perspective views of the mirror assembly 400 during the assembly process according to one or more embodiments. As shown in FIG. 13a, in the first assembly step, the mirror housing 402 (accommodating the HUD mirror) is moved vertically downward with respect to the bracket 406, as indicated by the arrow 404. During the first assembly step, the side pegs 408 of the mirror housing 402 will be seated on the lower surface 410 of the slot 412. As shown in FIG. 13b, in the second assembly step, the mirror housing is laterally moved relative to the bracket 406, as indicated by arrow 414. As shown in FIG. 13c, during the second assembly step, the support surface 416 of the side pegs 408 of the mirror housing 402 becomes seated on the rear surface 418 of the slot 412. This is the intended final assembly form. In one or more embodiments, the two-axis (ie, downward vertical axis and lateral axis) assembly method provides vertical and anteroposterior movement of the mirror housing 402 after completion of the assembly process. To prevent.

Although the above description relates to the relationship between the first side peg and the slot, the relationship between the second side peg and the slot may be configured in the same manner as the relationship between the first side peg and the slot.

Although exemplary embodiments have been described above, these embodiments are not intended to illustrate all possible embodiments of the invention. Rather, it is understood that the terms used herein are descriptive, not limiting, and that various modifications may be made without departing from the gist and scope of the invention. In addition, the features of various embodiments can be combined to form further embodiments of the invention.

10: HUD device, 12: instrument panel, 14: vehicle, 16: windshield, 18: virtual image, 20: vehicle occupant, 22: controller, 23: memory, 24: mirror, 26: display device, 28: screen, 30: Housing, 32: Medium, 33: Bracket, 34: Mirror assembly, 36: Drive unit, 100: Mirror assembly, 102: Mirror, 104: Housing, 106: Drive unit, 108: Bracket, 110: Peripheral frame part, 112: Rear body, 114: 1st side peg, 116: 2nd side peg, 118: Mounting part, 120: Peripheral edge, 122: Clasp, 124: Stopper, 126: 1st side wall, 128: 2nd side wall , 130: 1st mounting part, 132: 2nd mounting part, 134: 3rd mounting part, 136: 1st support arm, 138: 2nd support arm, 140: 1st vertical part, 142: 1st horizontal part, 144: 2nd vertical part, 146: 2nd horizontal part, 148: 3rd vertical part, 150: rack, 152: drive unit peg, 154: tension spring, 156: torsion spring

Claims (16)

A mirror that has anterior and posterior surfaces and extends along the longitudinal axis,
To accommodate the mirror as the front surface of the mirror is exposed, and the rear body portion peripheral frame portion and connected to each other, extends away from the peripheral frame portion, and first and second extending along a longitudinal axis Housing with 2 pegs,
A bracket having first and second attachments, including first and second slots, respectively, and a support arm extending between them.
Tensile springs attached to the rear body and support arm, and
A torsion spring, which exerts a holding force on the housing along the longitudinal axis from the second peg toward the housing,
The first peg has a peg slot having a shape obtained by scraping the surface of the first peg on a part of the side surface on the tip side thereof, and the peg slot is aligned with one side surface of the first peg. , Used to move the first peg to the bottom of the first slot, the surface of the first peg opposite the peg slot is at the bottom of the first slot and the first peg is the longitudinal axis. A head-up display (HUD) mirror assembly that remains seated on the other side of the first slot as a support surface when moving along the direction. The HUD mirror assembly of claim 1, wherein the support surface has a bow-shaped contour. The HUD mirror assembly of claim 1, wherein the support surface has a constant contour. The HUD mirror assembly of claim 1, wherein the first slot has a major axis and a minor axis, and the tension spring exerts a holding force in the direction perpendicular to and parallel to the major axis and along the first mounting portion. Peripheral frame extending along the longitudinal axis,
The rear main body connected to the peripheral frame and the rear body to accommodate the mirror so that the reflective surface of the mirror is exposed.
It extends away from the peripheral frame portion, and first and second peg extending along a longitudinal axis, comprising a,
The first peg has a peg slot having a shape obtained by scraping the surface of the first peg on a part of the side surface on the tip side thereof, and the peg slot is aligned with one side surface of the first peg. , Used to move the first peg to the bottom of the first slot, the surface of the first peg opposite the peg slot is at the bottom of the first slot and the first peg is the longitudinal axis. A head-up display (HUD) mirror housing that remains seated on the other side of the first slot as a support surface when moving along the direction. The HUD mirror housing according to claim 5 , wherein the support surface has a bow-shaped contour. The HUD mirror housing according to claim 5 , wherein the second peg has a second support surface configured to be supported by a second bracket mounting slot when the HUD mirror housing is in the assembled form. The HUD mirror housing according to claim 5 , wherein the first and second pegs are integrally formed with the rear main body portion. The first peg is the HUD mirror housing of claim 5 , which is terminated with an end cap. The HUD mirror housing according to claim 5 , wherein the slot of the first peg includes a bottom surface having a flat portion. A mirror having front and rear surfaces extending along a longitudinal axis, a peripheral frame portion and a rear main body portion connected to each other to accommodate the mirror so that the front surface of the mirror is exposed, and extending in a direction away from the peripheral frame portion and A housing with first and second pegs extending along the longitudinal axis, and a bracket with first and second attachments containing first and second slots, respectively, and a support arm extending between them. The first slot is a method of assembling a heads-up display (HUD) mirror assembly having a major axis and a minor axis.
Moving the housing vertically downward along the long axis so that the first peg sits on the underside of the first slot, and
A method comprising moving the housing laterally away from the bracket along a longitudinal axis such that the support surface of the first peg sits on the rear surface of the first slot. 11. A further aspect is that the tension spring is attached to the rear body and the support arm so that the tension spring exerts a holding force on the first peg along the first attachment in a direction perpendicular to the major axis. the method of. 11. The method of claim 11, further comprising using a torsion spring to exert a holding force on the housing along the longitudinal axis and exert a moment around the longitudinal axis from the second peg towards the housing. The method of claim 11 , wherein the first peg comprises a slot on the opposite side of the support surface. The method of claim 14 , wherein the slot of the first peg rides on the rear surface of the first slot of the first mounting portion during the first moving step. The method of claim 14 , wherein the slot of the first peg comprises a bottom surface having a flat portion.

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